Formation of bandgap and subbands in graphene nanomeshes with sub-10 nm ribbon width fabricated via nanoimprint lithography

Liang X.; Jung Y.-S.; Wu S.; Ismach A.; Olynick D.L.; Cabrini S.; Bokor J.

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Formation of bandgap and subbands in graphene nanomeshes with sub-10 nm ribbon width fabricated via nanoimprint lithography

机译：通过纳米压印光刻技术制备的亚纳米带宽小于10 nm的石墨烯纳米网中的带隙和子带的形成

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We fabricated hexagonal graphene nanomeshes (GNMs) with sub-10 nm ribbon width. The fabrication combines nanoimprint lithography, block-copolymer self-assembly for high-resolution nanoimprint template patterning, and electrostatic printing of graphene. Graphene field-effect transistors (GFETs) made from GNMs exhibit very different electronic characteristics in comparison with unpatterned GFETs even at room temperature. We observed multiplateaus in the drain current-gate voltage dependence as well as an enhancement of ON/OFF current ratio with reduction of the average ribbon width of GNMs. These effects are attributed to the formation of electronic subbands and a bandgap in GNMs. Such mesoscopic graphene structures and the nanofabrication methods could be employed to construct future electronic devices based on graphene superlattices.

机译：我们制造了色带宽度小于10 nm的六角形石墨烯纳米网（GNM）。该制造工艺结合了纳米压印光刻技术，用于高分辨率纳米压印模板图案化的嵌段共聚物自组装以及石墨烯的静电印刷。与无图案的GFET相比，即使在室温下，由GNM制成的石墨烯场效应晶体管（GFET）仍具有非常不同的电子特性。我们观察到漏极电流-门极电压依赖性具有多个平台，并且随着GNM的平均带宽度的减小，ON / OFF电流比得到增强。这些影响归因于GNM中电子子带的形成和带隙。这种介观的石墨烯结构和纳米制造方法可用于构建基于石墨烯超晶格的未来电子器件。

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《Nano letters》 |2010年第7期|共7页
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Liang X.; Jung Y.-S.; Wu S.; Ismach A.; Olynick D.L.; Cabrini S.; Bokor J.;
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1. Formation of bandgap and subbands in graphene nanomeshes with sub-10 nm ribbon width fabricated via nanoimprint lithography [J] . Liang X., Jung Y.-S., Wu S., Nano letters . 2010,第7期

机译：通过纳米压印光刻技术制备的亚纳米带宽小于10 nm的石墨烯纳米网中的带隙和子带的形成
2. Sub-10 nm Graphene Nanoribbon Array Field-Effect Transistors Fabricated by Block Copolymer Lithography [J] . Jeong Gon Son, Myungwoo Son, Kyeong-Joo Moon, Advanced Materials . 2013,第34期

机译：嵌段共聚物光刻技术制备的亚10纳米石墨烯纳米带阵列场效应晶体管
3. Sub-10 nm Nanoimprint Lithography by Wafer Bowing [J] . Wu W, Tong WM, Bartman J, Nano letters . 2008,第11期

机译：晶圆弯曲的亚10纳米纳米压印光刻
4. Plasmonic structures fabricated via nanomasking sub-10 nm lithography technique [C] . Stephen J. Bauman, Desalegn T. Debu, Joseph B. Herzog Nanoengineering: Fabrication, properties, optics, and devices XII . 2015

机译：通过纳米掩膜亚10纳米光刻技术制造的等离子结构
5. Towards Personal Health Monitoring: Detecting Biomolecules with Microfluidics and Nanoplasmonic Sensors Fabricated by Nanoimprint Lithography [D] . Peng, Ruoming. 2017

机译：迈向个人健康监测：利用纳米压印光刻技术制造的微流体和纳米等离子体传感器检测生物分子
6. Nanoelectrode Arrays Fabricated by Thermal Nanoimprint Lithography for Biosensing Application [O] . Alessandra Zanut, Alessandro Cian, Nicola Cefarin, 2020

机译：由热纳米压印光刻制造的纳米电极阵列用于生物传感应用
7. Formation of bandgap and subbands in graphene nanomeshes with sub-10 nm ribbon width fabricated via nanoimprint lithography [O] . Xiaogan Liang, Yeon-sik Jung, Shiwei Wu, 2010

机译：通过纳米压印光刻制作具有亚10nm带宽的石墨烯纳米粒子中的带隙和子带的形成

Formation of bandgap and subbands in graphene nanomeshes with sub-10 nm ribbon width fabricated via nanoimprint lithography

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